EP0451808A1 - Method for compacting, in particular a snow layer on a slope and device therefor - Google Patents

Abstract

In order to consolidate a layer (6) of snow, heating pipes (2) are arranged therein, standing up approximately perpendicularly from the ground (1), and accelerate the conversion process of the snow. <IMAGE>

Description

The invention relates to a method for solidifying a particularly inclined snow cover and a device for carrying out the method.

The snow of a blanket of snow undergoes a transformation process, starting with fresh fresh snow, within which there are a number of different stages, at the end of which there is melting or glacial ice formation. During the conversion process, depending on the various influences, there are conversion stages that cause different properties of the snow pack. As can be found in detail in the avalanche manual of the State of Tyrol, Tyrolia-Verlag Innsbruck-Vienna, the conversion process is divided into three phases, namely the degrading metamorphosis, during which the snow crystals shrink and the snow cover settles. then into the building metamorphosis, during which the snow crystals combine to form larger crystals, but there is no further lowering of the snow cover, and finally into the melting metamorphosis, during which the crystals melt, the water content increases and, with further reduction of the air pore space, the snow cover settles again.

There are stages in all three phases in which the bond to the ground or between individual layers of snow is low. In these stages, e.g. B. significantly increases the risk of avalanches. The snow shows high strength at the beginning of the melting metamorphosis, as long as the humidity is low, or also in further stages of the melting metamorphosis, when the water freezes again in the snow with a higher water content. This can be observed, for example, when there is a freeze-thaw change between night and day, when a superficial layer of crust forms.

The process of converting snow also depends on the temperature conditions. Each phase is accelerated by higher temperatures. The snowpack becomes warm on the one hand from the ground and on the other hand from the sun, whereby only the outermost layers are significantly influenced, since snow has a very poor thermal conductivity. Middle layers of a blanket of snow therefore change much more slowly.

The invention has now set itself the task of developing a method and a device that allow to solidify the snow cover of slopes, particularly at risk of avalanches, by accelerating the conversion process.

According to the invention, this is achieved in that these approximately vertically penetrating heat conduction paths are formed in the snow cover.

With the help of the heat conduction path that penetrates the snow cover, middle layers of snow are now also locally supplied with heat from the warmer layer of snow near the ground, which speeds up their conversion process. In addition, if the temperature conditions are appropriate, cold air is also supplied, which enables the melted snow to freeze again. Since the cold reaches the ground despite the snow cover, it also improves the bond to the ground by freezing on the surface. As tests have shown, the process according to the invention forms approximately frustoconical blocks of high-strength snow. For example, if the appropriate distances are selected, these can stabilize the entire snow cover and thus drastically reduce the risk of avalanches. The frustoconical blocks reach an upper diameter, which corresponds approximately to the height of the snow cover, and a lower diameter, which is approximately 50% larger. An application example could provide such heat conduction paths at a distance of between 10 m and 15 m from one another, with firn snow blocks having a base diameter of about 1.5 m to 2 m being formed at a snow height of 1 m to 1.5 m. The process is favored if the heat conduction paths are led into the ground, since this not only means heat from the snow layer near the ground, but also Geothermal energy is introduced directly into the middle layers of snow.

The method according to the invention for stabilizing snow on ski slopes, which is already present in the final stages of the melting metamorphosis, is also used, for example in the event of warm weather or rising temperatures in spring, as long as there is a corresponding nightly drop in temperature. In these cases, the cold that has melted down to the ground via the heat conduction paths in the snow cover can freeze during the day, which can maintain or extend the usability of the ski slope.

A device according to the invention for carrying out the method provides heat pipes which are raised approximately vertically from the ground, the height of which corresponds approximately to the maximum snow depth to be expected. The heat pipes can be fixed in holders to be placed on the floor or anchored in the floor, but they are preferably buried directly into the ground where possible. In contrast to conventional avalanche structures, in which massive rails are connected in a lattice-like manner and supported on a slope, which represent an obstacle to the sliding of the snow due to their flat effect, heat pipes according to the invention are not able due to their small diameter and the lack of cross-connections To form an obstacle to sliding. Heat pipes that can be used for this purpose are known. They represent a closed, quasi-isothermal system in which heat is transported by evaporation or evaporation and condensation of suitable liquid, in particular in capillary tracks or channels, with a thermal conductivity which is many times better than that of metals. Examples of heat pipes are shown, for example, in EP-B-217 777 and the publications cited therein.

It is preferably provided that a plurality of heat pipes are each bundled in a cladding tube which has peripheral openings, so that the heat pipes are protected as much as possible against mechanical external stresses. Around To be able to use the heat pipes for snow stabilization on ski slopes without arranging them in the passable area, a further embodiment provides that two heat pipes form upstanding end sections of a heat pipe laid on or in the ground. Thus, the upstanding end sections can be arranged at the edge of the ski slope and above the lying section, cold is supplied in particular to the surface of the earth that is too warm and the melted lowermost layer of snow.

• Fig. 1 schematisch einen Hang mit Wärmerohren,
• Fig. 2 vergrößert den Umgebungsbereich eines Wärmerohrbündels, und
• Fig. 3 einen Ausschnitt einer Schipiste.

The invention will now be described in more detail with reference to the figures of the accompanying drawings. Show it:

• 1 schematically shows a slope with heat pipes,
• 2 enlarges the surrounding area of a heat pipe bundle, and
• Fig. 3 shows a section of a ski slope.

The slope shown in Fig. 1 has areas of lower and areas of greater inclination. The angle of inclination for avalanches is between approximately 20 ° and 60 °, in particular between 30 ° and 45 °. Heat pipes 2 that form heat conduction paths or that are bundled in cladding tubes 3 penetrate the snow cover 6 and are in particular anchored in the ground 1, for example buried. The heat pipes 2 conduct heat from the ground 1 or the layer of snow near the ground to the middle layer and cold from the air or the top layer of snow into the middle layer and to the ground 1, the extent of the heat or cold transport depending on the general temperature conditions and the Temperature differences between day and night or between the ground and snow cover surface. The heat pipes 2 are arranged more densely in more inclined areas and less inclined areas can be left free.

Fig. 2 shows the surrounding area of a cladding tube 3, in which a bundle of heat pipes 2 is arranged, and which is buried in the ground. The heat pipes 2 can extend in a root-like manner on the underside into the surrounding area, and on the not shown upper end of the cladding tube 3, a cover is preferably attached. The cladding tube 3, which is made in particular of metal and has a clear diameter of 6 cm, for example, has circumferential openings 4. The supply of heat or cold into the middle layers of the snow cover 6 also accelerates the conversion process of the snow there, so that within a few days a largely converted old or firn snow block 7 of high strength, approximately in the form of a truncated cone, forms in the snow cover , which also forms a good bond with the ground 1. A corresponding distribution of the heat pipes 2 on a slope at risk of avalanche therefore leads to the formation of sliding obstacles which prevent the slope from being discharged.

3 shows a variant of the erection and its arrangement on ski slopes 8. Each two heat pipes 2, which individually or bundled at the edge of the ski slope 8 pass through the snow cover 6, which is not shown here, approximately vertically, represent end sections of a heat pipe 5, which is preferably laid superficially in the ground and which crosses the ski slope 8. The heat pipes 5 serve to maintain the ski slope 8, which can therefore be used for an extended period of time, since, in the case of general warming, in the spring, for example, it enables the nightly cold to be fed into the water-containing layer of snow, which, like the surface layer, freezes as a result. Heat pipes 5, the end sections of which stand up, can also be provided to maintain or extend the usability of cross-country trails which contain not only inclined but also horizontal sections.

Claims (6)

Method for solidifying a snow slope, in particular inclined, characterized in that in the snow cover these heat conduction paths are formed which are approximately vertical. Method according to claim 1, characterized in that the heat conduction paths are led into the ground. Device for carrying out the method according to claim 1, characterized by heat pipes (2) standing upright from the ground (1). Device according to claim 3, characterized in that the heat pipes (2) are buried in the ground (1). Device according to claim 3 or 4, characterized in that in each case a plurality of heat pipes (2) are arranged bundled in a cladding tube (3) which has peripheral openings (4). Device according to one of claims 3 to 5, characterized in that two heat pipes (2) each form upstanding end sections of a heat pipe (5) laid on or in the ground (1).

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